Chris Jeynes University of Surrey Ion Beam Centre Guildford, England Monday February 23 rd 2009

1. The IAEA Intercomparison of IBA codesJoint ICTP/IAEA Workshop on Advanced Simulation and Modelling for Ion Beam Analysis23 - 27 February 2009, Miramare - Trieste, Italy Chris Jeynes University of Surrey Ion Beam Centre Guildford, England Monday February 23rd 2009

2. IAEA-sponsored intercomparison of IBA software codes Nuno P. Barradas (Instituto Tecnológico e Nuclear & University of Lisbon) Kai Arstila(Katholieke Universiteit Leuven) Gabor Battistig(MFA Budapest) E. Kótai & Edit Szilágyi(KFKI Budapest) Marco Bianconi & G. Lulli(CNR-IMM Bologna) Nick Dytlewski(IAEA, Vienna) Chris Jeynes(University of Surrey Ion Beam Centre) Matej Mayer(Max-Planck-Institut Garching) Eero Rauhala(University of Helsinki) Mike Thompson(Cornell University New York) Nuclear Instruments and Methods B262(2007) 281-303 summary at: Nuclear Instruments and Methods B266(2008) 1338-1342 This talk was presented at the IBA conference in Hyderabad, September 2007 http://www.mfa.kfki.hu/sigmabase/ibasoft/

3. Context • Status of software for Ion Beam Analysis in Materials Development, NAPC/PS/2002/F1.TM - 25886, (IAEA, Vienna 2003) • E. Rauhala, N.P. Barradas, S. Fazinić, M. Mayer, E. Szilágyi, M. Thompson, Status of ion beam data analysis and simulation software, Nucl. Instr. Meth. B244 (2006) 436 • Barradas & Rauhala chapter on IBA Software in new IBA Handbook (this has been circulated on ION) • IAEA cross-section CRP: A. Gurbich, I. Bogdanovic-Radovic, M. Chiari, C. Jeynes, M. Kokkoris, A.R. Ramos, M. Mayer, E. Rauhala, O. Schwerer, Shi Liqun and I. Vickridge, Status of the problem of nuclear cross section data for IBA, Nucl. Instrum. Methods Phys. Res., Sect. B, 266(2008)1198-1202 • PIXE & PIGE not considered here

4. Need for Intercomparison • Ion Beam Analysis is an accurate and traceable technique • IBA is not trivial to calculate: • The yield Ye at detected energy E3 for an element e is given by the triple integral: (D.K.Brice, Thin Solid Films 19 1973, 121) • Even in the single scattering approx. the calculation is intricate • Many physical effects to take care of • New generationsingle scattering codes • Monte Carlocode available for comparison • IAEA persuaded of need for support (cf IAEA support of IBANDL, SigmaCalc)

5. Depth profiling codes • First Generation Single Scattering Codes • Ziegler (1976) • GISA (Rauhala, 1984) • RUMP (Thompson, 1985) • RBX (Kótai, 1994) • Straggling Code • DEPTH (Szilágyi, 1995) • New Generation Single Scattering Codes • DataFurnace (“NDF” Barradas, Jeynes & Webb 1997) • SIMNRA (Mayer, 1997) • Monte Carlo Code • MCERD (Arstila, 2000)

6. Overview of Intercomparison • Comparative simulations • Baseline RBS (sanity check) • Screening • Pileup • Double scattering • Channelling • EBS with sharp resonances O(a,a)O: (3.04 MeV 4He) • ERD (1.5 MeV He) • HI-RBS (3.5 MeV Li) • HI-ERD (50 MeV I) • NRA (1 MeV 3He) • NRA (1 MeV D) • Detailed analysis of real spectra (RBS) • a-Si spectrum (sanity check) • IRMM certified Sb implant in Si • HfO/Si sample • Co-Re multilayer sample (roughness)

7. In=600, Out=300 Theta=1500 Baseline CalculationSimulation of 50nm Au/200nm SiO2/Si (1.5MeV 4He+, Bohr straggling, 16keV detector resolution, single pure Rutherford scattering, no pileup, SRIM 2003) All codes: 0.3% agreement: yield & height of various features SIMNRA, DataFurnace & RUMP: 0.1% yield & height agreement Surface & interface positions agree at 100eV SIMNRA, DataFurnace: Edge widths agree at 500eV

8. Simulation of 50nm Au/200nm SiO2/Si (1.5MeV 4He+, Bohr straggling, 16keV detector resolution, single Rutherford scattering with screening, no pileup, SRIM 2003) Same as previous, but with L’Ecuyer and Andersen screening Gold signal SIMNRA & DataFurnace indistinguishable, RUMP very close

9. Simulation of 50nm Au/200nm SiO2/Si (1.5MeV 4He+, Bohr straggling, 16keV detector resolution, single pure Rutherford scattering, pileup no PUR, SRIM 2003) Same as previous but with pileup and no pileup rejection SIMNRA & DataFurnace almost indistinguishable: difference due to slight variation in pileup treatment RUMP very close

10. Simulation of 50nm Au/200nm SiO2/Si (1MeV 4He+, Bohr straggling, 16keV detector resolution, screened Rutherford scattering, pileup, SRIM 2003, multiple & double scattering) Same as previous, but with double scattering and pileup SIMNRA & DataFurnace almost indistinguishable

11. Simulation of Channelling100% substitutional 66keV 1016 Ge/cm2 implant into bulk (100)Si; Si point defect distribution = Ge distribution but with 2% max concentration, Perfect (unreconstructed) surface Only RBX Comparison with Monte Carlo code BISIC is impressive BISIC:E. Albertazzi, M. Bianconi, G. Lulli, R. Nipoti, M. Cantiano, Nucl. Instrum. Methods B118 (1996) 128

12. In=600, Out=300 Theta=1500 EBS with sharp resonancesSimulation of 50nm Au/200nm SiO2/Si 3.15 MeV 4He+, Bohr straggling, SigmaCalc cross-sections for O(a,a)O. 3043keV resonance: 10*Rutherford 4% agreement between SIMNRA, DataFurnace, RUMP in region of sharp resonance Significant algorithmic differences: DataFurnace algorithm demonstrably superior N.P. Barradas, E. Alves, C. Jeynes, M. Tosaki, Nucl. Instrum. Methods B247 (2006) 381-389A.F. Gurbich, C. Jeynes, Nucl. Instrum. Methods B265 (2007) 447-452

13. In=150, Out=150 (angle to surface) Theta=300 1.8MeV 4He ERD, SigmaCalc cross sections Simulation of CD2 150nm/CH2 150nm/CD2 150nm 16keV detector resolution, Bohr straggling 6mm mylar range foil DataFurnace and SIMNRA agree at: 0.1% (yields), 400eV (edge positions) ~800eV (edge widths) Excellent agreement with MCERD

14. In=600, Out=300 Theta=1500 Heavy Ion RBSSimulation of 50nm Au/200nm SiO2/Si(3.5MeV 7Li+, Bohr straggling, 16keV detector resolution, pure Rutherford scattering, pileup, SRIM 2003) GISA: SRIM91 RUMP, SIMNRA, DataFurnace agree at: 0.3% (Yield/Height) 700eV (edge pos’ns) SIMNRA, DataFurnace agree at: 800eV (edge widths)

15. In=100, Out=300 (angle to surface) Theta=400 Heavy Ion ERDSimulation of 50nm Au/200nm SiO2/Si (50MeV 127I10+, Bohr straggling, 200keV detector resolution, SRIM 2003, multiple scattering) MCERD not known to be good Analytical codes appear to have 20% error on scattered I signal Outstanding problem

16. In=00, Out=100 Theta=1700 1MeV 3He+ NRASimulation of CD2 150nm/CH2 150nm/CD2 150nm d(3He, 4He)p d(3He, p)4He Q=18.35MeV 1980 cross-sections 6um range foil Low energy (4He) signal hard to calculate. NDF carries calculation to lower energies Excellent agreement for p signal W. Möller and F. Besenbacher, Nucl. Instr. and Meth. 168 (1980) 111

17. In=00, Out=100 Theta=1700 1MeV 2H+ NRASimulation of a bulk Fe4N sample 14N(d,a)12C Q=13.57MeV 1mb/sr 6um range foil Inverse kinematics below 550keV

18. Real Spectrum of a-Sia-Si, 2MeV, 3.840(8)keV/ch, 1.95(2)msr, 150.0(2)0 scattering angle, 46.0(5)uC “… all the codes obtain excellent agreement in the important high energy region of the Si signal” G. Lulli, E. Albertazzi, M. Bianconi, G.G. Bentini, R. Nipoti, R. Lotti, Nucl. Instrum. Methods B170 (2000) 1.

19. O 1.5MeV 4He+ 1500 & 1700 detectors Si Sb Real Spectra of Certified Implant481(3).1013/cm2 Sb implant in 90nm oxide/a-Si/c-Si Counting statistics: 0.05% Gain uncertainty: 0.3% Total experimental uncertainty (excluding stopping): 0.8% Certified Sb implanted sample: K. H. Ecker, U. Wätjen, A. Berger, L. Persson, W. Pritzcow, M. Radtke, H. Riesemeier, NIM B188 (2002) 120 Sb fluence determined using SRIM 2003 stopping: 481.15(55).1013/cm2 (0.1%)

20. HfO2/Si, 2.5MeV 4He+, 1650 scattering SigmaCalc cross-sections for O (2*Rutherford at 2.5MeV) Assuming HfOx result is: 296(4) ×1015 Hf/cm2 599(5) ×1015 O/cm2 2.96(8) ×1015 Zr/cm2 Uncertainty consistent with counting statistics

21. Glancing exit geometry Si bulk / Re 5nm/(Co 2nm/Re 0.5 nm)15 1 MeV 4He RBS, 1600scattering, 15 keV Average layer thickness DataFurnace: 356(30).1013Re/cm2 207(17).1014Co/cm2 SIMNRA: 368(31).1013Re/cm2 227(13).1014Co/cm2 Average layer thickness difference (normalised) 28pm for the Re layers and 94pm for the Co layers Roughness in conformal layers equivalent to features 0.6nm high and 40nm wide N.P. Barradas, J.C. Soares, M.F. da Silva, F. Pászti, and E. Szilágyi, Nucl. Instrum. Methods B 94 (1994) 266 ; N.P. Barradas, Nucl. Instrum. Methods B190 (2002) 247

22. Conclusions (I) • All codes perform to design • New generation codes (DataFurnace & SIMNRA) • Simulation results usually almost indistinguishable • Excellent results for RBS, HI-RBS, ERD (also RUMP) • Excellent results for EBS • Excellent results for NRA (including inverse kinematics) • Fair results for HI-ERD (also RBX) • Roughness and double scattering approximated • Accurate pileup (good in RUMP) • MCERD comparison • Need MC code for HI-ERD! • MC code is completely independent algorithmically • Equivalent results from MC code validates analytical codes • Summary • All codes give reasonable results • For HI-ERD you need MCERD • For channelling you need RBX (or a Monte Carlo code) • Otherwise, for best results you need DataFurnace or SIMNRA

23. Conclusions (II) • Code validation: 0.1% agreement at best • SIMNRA and DataFurnace are usually indistinguishable • Independent implementation of same algorithms • Independent algorithms (MCERD) also agree • Incidental demonstration that SRIM03 stopping powers are (accidentally) correct (at 0.6%) for 1.5MeV 4He on Si (best stopping powers are currently known at only 2%) • Thanks to IAEA! Nuclear Instruments and Methods B262 (2007) 281-303 summary at: Nuclear Instruments and Methods B266 (2008) 1338-1342 http://www.mfa.kfki.hu/sigmabase/ibasoft/